Activated antigen-specific T cells produce a variety of effector molecules for clearing infection, but also contribute significantly to inflammation and tissue injury. Here we report an anti-inflammatory property of anti-viral CD8+ and CD4+ effector T cells (Te) in the infected periphery during acute virus infection. We find that, during acute influenza infection, IL-10 is produced in the infected lungs at high levels -- exclusively by infiltrating virus-specific Te, with CD8+ Te contributing a larger fraction of the IL-10 produced. These Te in the periphery simultaneously produce IL-10 and proinflammatory cytokines, and express lineage markers characteristic of conventional Th/c1 cells. Importantly, blocking the action of the Te-derived IL-10 results in enhanced pulmonary inflammation and lethal injury. Our results demonstrate that anti-viral Te exert regulatory functions -- that is, fine-tune the extent of lung inflammation and injury associated with influenza infection by the production of an anti-inflammatory cytokine. The potential implications of these findings for infection with highly pathogenic influenza viruses are discussed.
The respiratory tract is constantly exposed to the external environment, and therefore, must be equipped to respond to and eliminate pathogens. Viral clearance and resolution of infection requires a complex, multi-faceted response initiated by resident respiratory tract cells and innate immune cells and ultimately resolved by adaptive immune cells. Although an effective immune response to eliminate viral pathogens is essential, a prolonged or exaggerated response can damage the respiratory tract. Immune-mediated pulmonary damage is manifested clinically in a variety of ways depending on location and extent of injury. Thus, the antiviral immune response represents a balancing act between the elimination of virus and immune-mediated pulmonary injury. In this review, we highlight major components of the host response to acute viral infection and their role in contributing to mitigating respiratory damage. We also briefly describe common clinical manifestations of respiratory viral infection and morphological correlates. The continuing threat posed by pandemic influenza as well as the emergence of novel respiratory viruses also capable of producing severe acute lung injury such as SARS-CoV, MERS-CoV, and enterovirus D68, highlights the need for an understanding of the immune mechanisms that contribute to virus elimination and immune-mediated injury.
Respiratory dendritic cells (RDC) are believed to play a central role in the induction of adaptive immune responses to pulmonary infection. Herein we examine the basal migration of RDC from the lungs to secondary lymphoid tissues and their enhanced maturation/migration after pulmonary infection/inflammation. We demonstrate that the accelerated migration of RDC to the draining peribronchial lymph nodes occurs only during the first 24 hr after pulmonary virus infection. RDC are refractory to further migration thereafter in spite of ongoing virus replication and pulmonary inflammation. We further demonstrate that induction of this RDC refractory state suppresses additional RDC mobilization to subsequent pulmonary virus infection and results in concomitant suppression of an antiviral pulmonary CD8(+) T cell response.
Dendritic cells located at the body surfaces, e.g. skin, respiratory and gastrointestinal tract, play an essential role in the induction of adaptive immune responses to pathogens and inert antigens present at these surfaces. In the respiratory tract, multiple subsets of dendritic cells (RDC) have been identified in both the normal and inflamed lungs. While the importance of RDC in antigen transport from the inflamed or infected respiratory tract to the lymph nodes draining this site is well recognized, the contribution of individual RDC subsets to this process and the precise role of migrant RDC within the lymph nodes in antigen presentation to T cells is not clear. In this report, we demonstrate that two distinct subsets of migrant RDC - exhibiting the CD103+ and CD11bhi phenotype, respectively - are the primary DC presenting antigen to naïve CD4+ and CD8+ T lymphocytes in the draining nodes in response to respiratory influenza virus infection. Furthermore, the migrant CD103+ RDC subset preferentially drives efficient proliferation and differentiation of naive CD8+ T cells responding to infection into effector cells, and only the CD103+ RDC subset can present to naïve CD8+ T cells non-infectious viral vaccine introduced into the respiratory tract. These results identify CD103+ and CD11bhi RDC as critical regulators of the adaptive immune response to respiratory tract infection and potential targets in the design of mucosal vaccines.
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